CN113253163A - Full-tensor magnetic field gradient measurement device and method for quad-rotor unmanned aerial vehicle platform - Google Patents

Abstract

The invention discloses a full-tensor magnetic field gradient measuring device and method facing a quad-rotor unmanned aerial vehicle platform.A total of four sensors which are arranged at the end parts of sole support frames at the left side and the right side of an unmanned aerial vehicle through hinges and a sensor which is hoisted below the unmanned aerial vehicle through a support rod driven by a steering engine are designed; adopt the overall arrangement mode of the sensor of adaptation in four rotor unmanned aerial vehicle platforms, still realize the collapsible function of device through the hinge. Meanwhile, the position of each sensor can be adjusted, so that the base line can be adjusted, and the base line can be dynamically adjusted according to the measurement range and the strength of the magnetic field of the magnetic target. The invention realizes a magnetic characteristic detection system with low cost, miniaturization, small range area, high precision, networking and multiple characteristics.

Description

Full-tensor magnetic field gradient measurement device and method for quad-rotor unmanned aerial vehicle platform

Technical Field

The invention is used for novel aerial magnetic survey of an unmanned aerial vehicle platform, and relates to an aerial full tensor magnetic field gradient measuring device and method facing a quadrotor unmanned aerial vehicle platform, in particular to an aerial full tensor magnetic field gradient measuring device facing the quadrotor unmanned aerial vehicle platform and a measuring method for obtaining a full tensor magnetic field gradient.

Background

The magnetic characteristic detection system is widely applied to the fields of land and ocean resource exploration, infrastructure construction exploration, magnetic target positioning, spacecraft magnetic characteristic ground test and the like. The magnetic characteristic detection technology is used for detecting magnetic abnormal characteristics by utilizing the principle that a magnetic field generated by a magnetic substance or a magnetic target is magnetized under the action of the earth magnetic field and the earth magnetic field is disturbed. Compared with other physical quantity detection, the magnetic characteristic detection has the advantages of fast response, high efficiency, wide application range, strong concealment and the like, and is one of the key technologies of the modern geophysical prospecting technology cooperative test.

In view of the wide application range, more sophisticated aviation magnetic feature detection systems have been developed in recent years. Table 1.1 summarizes the 9 more mature aviation magnetic signature detection system parameters at home and abroad.

TABLE 1.1 more mature aeromagnetic signature detection systems and parameters at home and abroad

The investigation result shows that: the carrier aircrafts of the mature aviation magnetic characteristic detection system are fixed-wing aircrafts, helicopters and the like. The magnetic characteristic detection system adopting the aircraft has the advantages of stability, small influence of uncontrollable weather conditions such as wind power and the like. The magnetic sensor system can be used for carrying a magnetic sensor system with heavier weight, more quantity and larger volume, and the detected data is more accurate. However, there are the following major problems:

(1) the price is expensive: the take-off price of large fixed-wing aircrafts and helicopters is high, and related documents show that the price for carrying out 1-day helicopter operation is up to 20 ten thousand yuan, wherein the cost for renting and maintaining various instruments and the labor cost of pilots and related personnel are not included.

(2) The volume and the weight are huge: the upper surface aviation magnetic detection system mainly adopts an optical pump magnetometer array magnetic field measurement system and a superconducting quantum interferometer array measurement system. The system occupies large volume and heavy weight, and the volume interval of the whole device is 88-998 m during operation³The weight range of the whole device is 650-28300 kg, which causes inconvenience in transportation and application.

(3) The efficiency is low: professional aircraft operating platforms require the employment of professional pilots and professional maintenance personnel, which makes the operation complicated when the operation is performed, and the related coordination and scheduling are complicated. And because the integration of the system is not strong, the data arrangement is more complicated, so that the magnetic characteristic detection work efficiency is low.

(4) Only for large areas: because the whole operation device is large in size and weight, and the device is easy to magnetize, the magnetic characteristic extraction is influenced, when the device is applied, the magnetic characteristic analysis can be performed only in a large-range area, and the magnetic characteristic analysis in a small-range area has large errors due to the inherent magnetic field influence of a large aircraft and the requirement of high resolution.

(5) The magnetic characteristics are single: can only provide magnetic field intensity | B |, magnetic field vector B, intensity gradient

And (6) measuring.

Disclosure of Invention

Aiming at the current situation of the industry, the invention provides an aviation full tensor magnetic field gradient measuring device and method for a quad-rotor unmanned aerial vehicle platform, which realize low cost and miniaturization (the weight is not more than 1kg, and the volume is not more than 0.25 m)³) Aiming at a small-range area (20-1000 m)²) Higher precision (nano-tex), networked, multi-feature (intensity, vector, gradient, and tensor) magnetic feature detection systems.

The invention relates to a full-tensor magnetic field gradient measuring device for a quad-rotor unmanned aerial vehicle platform, which comprises four sensors distributed on the horizontal plane at the bottom of a sole support frame of an unmanned aerial vehicle, sole support frame end parts respectively arranged at the left side and the right side of the unmanned aerial vehicle, and a sensor hanging on a pendant below the unmanned aerial vehicle, wherein the center of the sensor is positioned at the midpoint position of a connecting line of the centers of two sensors at the front side or the rear side of the unmanned aerial vehicle.

Four sensors that above-mentioned unmanned aerial vehicle's sole support frame bottom horizontal plane distributes are connected through foldable sensor mount device between sole support frame, by foldable sensor mount device inwards fold or outwards expand on sole support frame bottom horizontal plane.

The sensor of unmanned aerial vehicle below pendant is installed in the hoist and mount bracing piece bottom of being driven pivoted by drive arrangement, drives the hoist and mount bracing piece by drive arrangement.

The base line is adjustable, and the specific mode is as follows: a slideway is designed on the folding sensor mounting device, and the sensor is connected by penetrating through the slideway through a bolt; when the foldable sensor mounting device is unfolded, the position of the sensor in the left and right directions of the unmanned aerial vehicle is adjusted by the sliding of the sensor along the slide way; the foldable sensor mounting device is connected with the end part of the sole support frame through the telescopic sleeve, and when the foldable sensor mounting device is unfolded, the position of the sensor in the front-back direction of the unmanned aerial vehicle is adjusted through the telescopic action of the telescopic sleeve;

the hoisting support rod is connected with the driving device through the telescopic sleeve; when the hoist and mount bracing piece expandes, realize the position control of sensor orientation about unmanned aerial vehicle through telescopic flexible.

The full-tensor magnetic field gradient measuring device with the structure has the advantages that the base line is adjustable, and the specific mode is as follows: a slideway is designed on the folding sensor mounting device, and the sensor is connected by penetrating through the slideway through a bolt; when the foldable sensor mounting device is unfolded, the position of the sensor in the left and right directions of the unmanned aerial vehicle is adjusted by the sliding of the sensor along the slide way; the foldable sensor mounting device is connected with the end part of the sole support frame through the telescopic sleeve, and when the foldable sensor mounting device is unfolded, the position of the sensor in the front-back direction of the unmanned aerial vehicle is adjusted through the telescopic action of the telescopic sleeve;

the hoisting support rod is connected with the driving device through the telescopic sleeve; when the hoist and mount bracing piece expandes, realize the position control of sensor orientation about unmanned aerial vehicle through telescopic flexible.

The measurement method for the full-tensor magnetic field gradient measurement device-oriented quad-rotor drone platform of claim 1, comprising the steps of:

step 1: unfolding the foldable sensor mounting device, and adjusting the base length of the x axis, the y axis and the z axis according to the magnetic target; wherein the y-axis is along the left and right directions of the unmanned aerial vehicle; the x axis is along the front and back directions of the unmanned aerial vehicle; the z-axis is along the up-down direction of the unmanned aerial vehicle.

Step 2: calibrating the navigation angle of the unmanned aerial vehicle and recording; the central points of the two sensors on the same side of the unmanned aerial vehicle are calibrated by using a straight line or a ruler are positioned on the same straight line.

And step 3: taking off, and then remotely controlling the steering engine to drive the hoisting support rod to be completely unfolded along the z-axis direction.

And 4, step 4: the three-axis magnetic field is acquired in real time through five sensors.

And 5: the full tensor magnetic field gradient is calculated.

The invention has the advantages that:

1. the invention relates to a full-tensor magnetic field gradient measuring device for a quad-rotor unmanned aerial vehicle platform, which adopts a foldable design: in theory, the measurement of the 9 components of the full tensor magnetic field gradient needs to be differentiated for the three-axis magnetic field. In engineering, due to limited sensor precision, a differential method is applied to replace differentiation, and the differential method requires that the sensors on the same shaft are spaced by a certain distance, so that the whole device is large in size. The invention adopts a folding design based on a hinge structure, and can reduce the volume of the whole device to the limit, namely close to the volume of a four-rotor aircraft when not in work. The folding action is completed by rotating the sensor supporting rod by hands or a steering engine by 0-90 degrees at the center of the hinge structure through the hinge structure. Meanwhile, in order to reduce the bearing power of the steering engine, a spring device is arranged on a hinge of the folding device in the vertical direction, and the spring device can also be used as a safety device when the steering engine fails.

2. The invention relates to a full-tensor magnetic field gradient measurement device and method for a quad-rotor unmanned aerial vehicle platform, wherein a base line is adjustable: the baseline, i.e. the distance between two sensors on one axis of the full-tensor gradiometer, is generally divided into x-axis, y-axis and z-axis baselines. When the full-tensor magnetic field gradient is subjected to engineering calculation, the difference of the three-axis magnetic fields of the two sensors on the same axis needs to be divided by the length of the base line of the axis. When the full tensor magnetic field gradient measuring device works in the aviation, the measured purposes are different. The difference of purposes leads to the difference of the unmanned aerial vehicle measurement range and the response strength of the three-axis magnetic field. At this time, the baseline can be dynamically adjusted according to the measurement range and the magnetic field strength of the magnetic target. The base line is adjusted to be small, so that non-common mode magnetic field noise can be reduced; the baseline is enlarged, so that the difference value of the two sensors on the same axis can be increased, and the magnetic field gradient measurement precision can be improved.

3. The aviation full tensor magnetic field gradient measuring device facing the quadrotor unmanned aerial vehicle platform adopts a layout mode of sensors adapted to the quadrotor unmanned aerial vehicle platform: but four rotor unmanned aerial vehicle of general load all possess the sole support frame so that rise and fall. The invention utilizes the sole support frame, the sensors are respectively arranged at the two ends of the two sole support frames, and the sensors are totally four, so that the sensor array of the x axis and the y axis is formed. In addition, compared with the traditional three-sensor layout mode, the layout mode of the x axis and the y axis introduces one more three-axis sensor, and the two pairs of four sensors in the same axial direction can be used for calculation, so that the common mode noise of the magnetic field can be further inhibited. For the z-axis sensor, set up in the unmanned aerial vehicle below, can set up under the central point of two sensors on same axis, also can set up under the central point of the rectangle that four sensors constitute. Compared with the traditional layout method for arranging the z-axis sensor above the unmanned aerial vehicle, the layout method of the z-axis sensor provided by the invention has the advantages that the interference of a magnetic source in the full-tensor magnetic field gradient measuring device (the interference of the magnetic source of a motor, an antenna and an internal circuit of a machine body) is reduced to the maximum extent, the magnetic source carried on the unmanned aerial vehicle is converted into common-mode noise, and the suppression is realized through the operation of the full-tensor magnetic field gradient.

Drawings

FIG. 1 is a schematic diagram of a layout of a magnetic sensor of the full tensor magnetic field gradient measuring device according to the present invention;

fig. 2 is a schematic structural diagram of an unfolding state of the aviation full tensor magnetic field gradient measuring device facing a quad-rotor unmanned aerial vehicle platform;

fig. 3 is a schematic structural diagram of a folded state of the aviation full tensor magnetic field gradient measuring device facing a quad-rotor unmanned aerial vehicle platform;

fig. 4 is a schematic diagram of a buffer design in the aviation full tensor magnetic field gradient measurement device facing the quad-rotor unmanned aerial vehicle platform.

In the figure:

1-sole support frame 2-horizontal folding support rod 3-sole support frame connector

4-sensor 5-driving device 6-hoisting support rod

7-notch 8-spring 9-ball

10-slideway 11-sleeve 301-joint

501-bracket 502-steering engine drive plate 503-steering engine

504-Power supply Module

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The invention relates to a full-tensor magnetic field gradient measuring device for a four-rotor unmanned aerial vehicle platform, which firstly considers that the full-tensor magnetic field gradient aims at the analysis of one point and needs differential operation. In engineering, due to the limited accuracy of magnetic sensors, differences are used instead of differentials to complete the approximate calculation of the full tensor magnetic field gradient. Since the difference between the two sensors requires a significant difference in value, the two sensors need to be spaced apart from each other. Based on the reasons, the layout method for designing the full tensor magnetic field gradient sensor comprises the following steps:

as shown in fig. 1, four sensors 4 are distributed on the bottom horizontal surface of the sole support frame of the unmanned aerial vehicle, and are respectively installed at the end parts of the sole support frame 1 on the left and right sides (y-axis direction) of the unmanned aerial vehicle. Simultaneously, sensor 4 of unmanned aerial vehicle below pendant, this sensor 4 design has two kinds of position to select:

1. the center of the sensor 4 is positioned at the midpoint position of the connecting line of the centers of the two sensors 4 on the front side or the rear side of the unmanned aerial vehicle.

2. Sensor 4 is located the unmanned aerial vehicle fuselage under, and four sensor 4 central points of sole support frame 1 horizontal plane line constitute the center (the crossing point of diagonal) position of rectangle promptly.

In the invention, the ultrasonic distance meter is usually arranged under the unmanned aerial vehicle body, so that the 1 st position is selected for setting the sensor 4. By the layout method of the sensor 4, magnetic source interference existing in the full-tensor magnetic field gradient measuring device can be avoided, errors are reduced, and calibration difficulty is reduced.

In the full-tensor magnetic field gradient measuring device, the volume of the full-tensor magnetic field measuring device is considered to be larger, so that the folding type sensor mounting device is designed in the invention, and the five sensors 4 in total involved in the layout method are mounted, and the method comprises the following steps:

two sensors 4 at the end part of a left sole support frame 1 of the unmanned aerial vehicle are left sensors, two sensors 4 at the end part of a right sole support frame 1 of the unmanned aerial vehicle are right sensors, and a sensor 4 of a pendant below the unmanned aerial vehicle is a central sensor; then two left sensors and two right sensors all hinge between 1 tip of hinge and sole support frame, as shown in fig. 2, fig. 3, and the concrete mode is:

the hinge comprises a horizontal folding supporting rod 2 and a sole supporting frame connector 3. The horizontal folding support rod 2 is positioned in the horizontal plane at the bottom of the sole support frame, and a sensor 4 is arranged on the horizontal folding support rod. The sole support frame connector 3 is of a sleeve structure, a hinge joint 301 is designed at the hinge end, and the hinge joint 301 is meshed with the hinge end of the horizontal folding support rod 2 to form a revolute pair. The horizontal folding support rods 2 are perpendicular to the axis of the sole support frame connector 3, the connecting ends of the sole support frame connector 3 are matched with the end portions of the sole support frame 1 in an inserting mode, fixing between the hinge and the sole support frame 1 is achieved, the rotation pair axis of the hinge is perpendicular to the horizontal plane of the bottom of the sole support frame 1, each horizontal folding support rod 2 can be folded inwards or unfolded outwards on the horizontal plane of the bottom of the sole support frame 1 around the rotation pair of the hinge, and the folding and unfolding angles of the horizontal folding support rods 2 are 0-90 degrees. Wherein the relative rotation of two bracing pieces 2 in the folding interior including unmanned aerial vehicle left side to and two horizontal folding bracing pieces 2 in unmanned aerial vehicle right side, extreme position is the coincidence of 2 axes of homonymy horizontal folding bracing piece. The outward unfolding is the reverse movement of the inward folding, and the limit position is that the axis of the horizontal folding support rod 2 is vertical to the axis of the sole support frame 1. After the position of the horizontal folding supporting rod 2 is determined, the hinge can be locked through the bolt, so that the phenomenon of shaking during operation is avoided.

The installation mode of the central sensor is as follows:

the sensor 4 is arranged at the bottom end of a hoisting support rod 6 driven by a driving device 5 to rotate. The driving device 5 includes a bracket 501, a steering engine driving board 502, a steering engine 503 and a power module 504. Support 501 both ends design annular cover cup joints respectively in unmanned aerial vehicle left and right sides sole support frame 1 homonymy tip position, simultaneously with fixed between the tip, realize the location between support 501 and sole support frame 1. A plurality of slot positions are designed on the bracket 501 and are respectively provided with a steering engine driving plate 502, a steering engine 503 and a power module 504; meanwhile, one side of the middle of the support 501 is provided with a notch 7 as a support rod connecting groove, the top of the hoisting support rod 6 is arranged in the notch 7, and the output shaft of the steering engine 503 is perpendicular to the sole support frame 1 and is fixedly connected with the top of the hoisting support rod 6. From this, power door module is the power supply of steering wheel drive plate 502 and steering wheel 501, is controlled the motion of steering wheel 503 by steering wheel drive plate 502, and then is folded or is rotated the expansion downwards to the inboard top around the output shaft of steering wheel 503 by steering wheel 501 drive hoist and mount bracing piece 6, makes the folding and the expansion angle of hoist and mount bracing piece 6 be 0 ~ 90 degrees. When the sole support frame is folded to the limit position towards the upper side of the inner side, the axis of the hoisting support rod 6 is positioned in the horizontal plane of the bottom surface of the sole support frame 1; the outward unfolding is the reverse movement of the inward folding, and the limit position is that the axis of the horizontal folding support rod 2 is vertical to the horizontal plane of the bottom surface of the sole support frame 1.

For the safety and energy conservation, the folding hinge of the lower pendant supporting structure of the unmanned aerial vehicle is provided with a spring structure, and the spring structure comprises a spring 8 and a ball 9, as shown in fig. 4. The spring 8 and the ball 9 are arranged in a spring cavity arranged at the corresponding position of the opposite side surfaces of the gap 7, and the ball part is positioned outside the opening of the section of the spring cavity under the action of the elastic force of the spring. When the spring 8 is in a free state, part of the ball 9 is exposed out of the spring cavity; from this when the folding in-process of hoist and mount bracing piece 6, relative both sides contact ball 9 respectively, further extrude ball 9, and spring 8 contracts, and after hoist and mount bracing piece 6 rotated 90 degrees, ball 9 imbeds in the recess of design on the relative both sides of hoist and mount bracing piece 6 this moment, reaches fold condition completely. Under the complete folding state of the hoisting support rod 6, the interaction force between the groove and the ball 9 is changed into the interaction force between the hoisting support rod 6 and the spring 8. The acting force can help the hoisting support rod 6 to be buffered when in a completely folded state in the z-axis direction, so that the bearing power of the steering engine is reduced, and meanwhile, the acting force can also be used as a safety device when the steering engine 401 is out of order.

Based on the design of the folding type sensor mounting device and the layout of the sensors, the measured purpose is different when the full tensor magnetic field gradient measuring device works. The difference of purposes leads to the difference of the unmanned aerial vehicle measurement range and the response strength of the magnetic characteristics. For example, when the magnetic characteristics of a magnet with a large volume are described by using a full-tensor magnetic field gradient measurement device, the unmanned aerial vehicle is close to the magnet, the magnetic characteristics are obvious, and the baseline can be properly reduced to reduce errors; the baseline is the distance between two sensors in the full tensor magnetic field gradient measuring device, and the two sensors need to be on the same axis of a rectangular coordinate system, so the two sensors are generally divided into x-axis baselines, y-axis baselines and z-axis baselines. In addition, when a mountain range is scanned by using the full-tensor magnetic field gradient measuring device to search mineral distribution, the unmanned aerial vehicle is far away from a magnetic source, the magnetic characteristic is weak, and at the moment, the base line needs to be enlarged to properly increase the range of measuring the magnetic characteristic.

Therefore, on the basis of the tensor magnetic field gradient measuring device with the structure, the invention also designs the adjustable baseline, and the specific mode is as follows:

for the adjustment of a base line in a y axis in a horizontal plane, namely the base line in the axial direction vertical to the sole support frame, the invention designs that a slide way 10 which penetrates through the horizontal folding support rods 2 up and down is arranged on each horizontal folding support rod 2 along the axial direction of the horizontal folding support rod, and the horizontal folding support rod is in threaded fit connection with threaded holes formed in the two opposite ends of the sensor 4 after two bolts penetrate through the slide way 10 from the lower part of the horizontal folding support rod 2, so that the installation between the sensor 4 and the horizontal folding support rod 2 is completed. When the bolt is loosened, the sensor 4 can slide along the slideway 10 to realize the adjustment of the base line in the y-axis direction, and the length range of the base line of the y-axis in the horizontal plane after the adjustment is 600-680 mm. After the sensor 4 slides to a proper position, the fixing between the sensor 4 and the horizontal folding supporting rod 2 is realized by screwing the bolt.

For the baseline adjustment of the x-axis in the horizontal plane, i.e. parallel to the axial direction of the sole support, the invention is implemented by a sleeve 11 arranged between the end of the sole support 1 and the joint 301. The sleeve 11 is formed by internally and externally nesting two tubular structures to form a sliding pair; wherein the outer layer pipe is sleeved at the end part of the sole support frame 1, and the end part of the inner layer pipe is sleeved with the hinge joint 301; thereby adjusting the length of the y-axis base line by adjusting the overlapping length of the two tubes. The sleeve 11 is locked by a locking structure, so that the inner-layer pipe and the outer-layer pipe are fixed. The locking structure consists of a circular hoop structure and a bolt, the circular hoop is sleeved at the end part of the outer layer pipe, and the circular hoop is locked by the bolt to fix the adjusted inner layer pipe; the length range of the base line in the x-axis direction in the horizontal plane after adjustment is 370 mm-450 mm.

For the adjustment of a base line of a z axis, namely, the base line in the axial direction perpendicular to the horizontal plane at the bottom of the sole support frame 1, the structure is the same as that of the adjustment of the base line of an x axis, and the hoisting support rod 6 is connected with the steering engine 501 through an inner layer sleeve structure and an outer layer sleeve structure. Wherein, the end part of the outer layer cylinder is fixedly connected with the steering engine 501, and the top ends of the supporting rods at the end part of the inner layer cylinder are connected; the circular hoop is sleeved at the end part of the outer layer pipe, and the circular hoop is locked through a bolt to fix the adjusted inner layer pipe; the length range of the base line in the z-axis direction is 400 mm-500 mm after adjustment.

Because the device is carried on the unmanned aerial vehicle, all the support structures are made of carbon fiber materials, and the device can meet the characteristics of light weight and firmness; meanwhile, the interference of the copper material to the surrounding magnetic field is small due to the metal characteristic of the copper, so that all metal fasteners are made of the copper material, such as bolts and the like.

Aiming at the full-tensor magnetic field gradient measurement method of the full-tensor magnetic field gradient measurement device for the quad-rotor unmanned aerial vehicle platform, the full-tensor magnetic field gradient measurement method specifically comprises the following steps:

step 1: and unfolding the horizontal folding support rod 2, and adjusting the base length of the x axis, the y axis and the z axis according to the magnetic target.

Step 2: and (6) calibrating the navigation angle and recording of the unmanned aerial vehicle. The central points of the two sensors 4 on the same side of the unmanned aerial vehicle are calibrated to be positioned on the same straight line by using a straight line or ruler; if not, each hinge is fine-tuned.

And step 3: taking off, and then driving the hoisting support rods 6 to be completely unfolded by the remote control steering engine 401.

And 4, step 4: and acquiring a three-axis magnetic field in real time through five magnetic sensors.

And 5: the full tensor magnetic field gradient is calculated.

The tensor magnetic field gradient of the x-axis is divided by twice the length of the x-axis baseline after the sum of the three-axis magnetic characteristics of the two sensors 4 in the same x-axis direction is subtracted from the sum of the three-axis magnetic characteristics of the two sensors 4 on the opposite side. The y-axis tensor magnetic field gradient is divided by twice the y-axis baseline length after subtracting the sum of the three-axis magnetic characteristics of the two sensors 4 in the same y-axis direction from the sum of the three-axis magnetic characteristics of the two sensors 4 on the opposite side. The z-axis tensor magnetic field gradient is divided by the two times of the z-axis base length after the subtraction of the sum of the three-axis magnetic characteristics of the two sensors on the same side of the central sensor and the two times of the three-axis magnetic characteristics of the central sensor.

As shown in FIG. 1, B_B、B_C、B_D、B_ERespectively a right front sensor, a left rear sensor, a B_AFor the sensor of the pendant below the unmanned aerial vehicle, the specific process of calculating the full tensor magnetic field gradient in step 5 is as follows:

wherein, B_xB、B_xC、B_xD、B_yEThe magnetic fields of the X axis measured by the sensors at the right back, the right front, the left front and the left back of the unmanned aerial vehicle respectively; b is_yB、B_yC、B_yD、B_zEThe y-axis magnetic fields measured by sensors at the right rear, the right front, the left front and the left rear of the unmanned aerial vehicle respectively; b is_zB、B_zC、B_zD、B_zERespectively measuring z-axis magnetic fields of sensors at the right rear, the right front, the left front and the left rear of the unmanned aerial vehicle; x is the number of₀、y₀、z₀The base lengths of the x-axis, the y-axis and the z-axis are respectively.

Example (b):

this embodiment describes the use of the present aviation full tensor magnetic field gradient measurement system to perform magnetic measurement in an outdoor environment of 2 square kilometers in height of 30 meters from the takeoff site.

The four-rotor unmanned aerial vehicle platform used is Xinjiang longitude and latitude M200.

The three-axis magnetic field sensor is a giant magnetoresistance three-axis magnetic sensor which is independently researched and developed and can measure three-axis magnetic field information in real time.

The aviation full tensor magnetic field gradient measuring device oriented to the quad-rotor unmanned aerial vehicle platform is adopted for measurement and comprises the following steps:

step 1: the four folding hinges of the x-y plane are opened by manually operating the folding hinges. The folding hinge is locked by copper bolts.

Step 2: and (5) calibrating the navigation angle of the unmanned aerial vehicle to be 99 degrees east, and recording. And (3) calibrating the central points of the sensors on the x axis and the y axis on the same straight line by using a straight line or ruler, and if not, finely adjusting the x-y plane hinge.

And step 3: and adjusting the base line, wherein the flight range is larger, so that the distance of the base line is adjusted to be the maximum, wherein the y-axis base line is 680mm, the x-axis base line is 450mm, and the z-axis base line is 500 mm.

And 4, step 4: the unmanned aerial vehicle takes off, and the flight scanning route of the unmanned aerial vehicle is set to S-shaped scanning. The scan range relates to 2 square kilometers.

And 5: and (3) unfolding the z axis: a control command is sent to the server through an MQTT protocol by using a mobile phone, and after the command is received by the steering engine control panel, the steering engine is controlled to enable the hoisting support rod 6 to be unfolded along the z-axis direction.

Step 6: the unmanned aerial vehicle starts to operate, and the unmanned aerial vehicle runs according to a specified route.

And 7: and (5) the unmanned aerial vehicle flies to a preset planning place, and the operation is finished. All data are downloaded to the terminal, and the full tensor magnetic field gradient of each point is calculated.

And 8: the unmanned aerial vehicle navigates back and hovers 5m above the starting position.

And step 9: retracting the z axis: utilize the cell-phone to send control command to the server through wireless transmission mode, after the steering wheel control panel received the command, control the steering wheel and make hoist and mount bracing piece 6 fold and pack up.

Step 10: unmanned aerial vehicle descends. The power is turned off. And (5) retracting the x-y plane folding bracket.

Claims (7)

1. Towards four rotor unmanned aerial vehicle platform's full tensor magnetic field gradient measuring device, its characterized in that: including four sensors that distribute at unmanned aerial vehicle's sole support frame bottom horizontal plane, install respectively in the sole support frame tip of the unmanned aerial vehicle left and right sides to and a sensor of unmanned aerial vehicle below pendant, the sensor center is located two sensor center line midpoint position of unmanned aerial vehicle front side or rear side.

Four sensors distributed on the horizontal plane of the bottom of the foot sole support frame of the unmanned aerial vehicle are connected with the foot sole support frame through a foldable sensor mounting device, and the foldable sensor mounting device is folded inwards or unfolded outwards on the horizontal plane of the bottom of the foot sole support frame;

the sensor of unmanned aerial vehicle below pendant is installed in the hoist and mount bracing piece bottom of being driven pivoted by drive arrangement, drives the hoist and mount bracing piece by drive arrangement.

2. The full-tensor magnetic field gradient measurement device oriented toward a quad-rotor drone platform of claim 1, wherein: the folding sensor mounting device is a hinge formed by a horizontal folding support rod and a sole support frame connector; wherein, a sensor is arranged on the horizontal folding supporting rod; the hinged end of the sole support frame connector is connected with the horizontal folding support rod to form a revolute pair; the connecting end of the sole support frame connector is fixedly connected with the end part of the sole support frame; and the axis of the rotation pair of the hinge is vertical to the horizontal plane at the bottom of the sole support frame.

3. The full-tensor magnetic field gradient measurement device oriented toward a quad-rotor drone platform of claim 1, wherein: the driving device comprises a bracket, a steering engine driving plate, a steering engine and a power supply module; two ends of the bracket are fixedly sleeved at the end parts of the left and right foot sole supporting frames on the same side of the unmanned aerial vehicle respectively; a steering engine driving plate, a steering engine and a power supply module are arranged on the bracket; meanwhile, one side of the middle part of the bracket is provided with a notch as a connecting groove position of a hoisting support rod, the top of the hoisting support rod is arranged in the notch, and an output shaft of the steering engine is arranged along the left and right direction and is fixedly connected with the top of the hoisting support rod; the power door module is used for supplying power to the steering engine driving plate and the steering engine, the steering engine driving plate controls the steering engine to move, and the steering engine drives the hoisting support rod to rotate around an output shaft of the steering engine.

4. The full-tensor magnetic field gradient measurement device oriented toward a quad-rotor drone platform of claim 3, wherein: the support is provided with a spring structure which comprises a spring and a ball; the spring and the ball are arranged in a spring cavity arranged in the corresponding position of the opposite side surface of the notch, and the ball part is positioned outside the opening of the end surface of the spring cavity under the action of the elastic force of the spring; when the hoisting support rod is folded, the two opposite sides of the hoisting support rod are respectively contacted with the balls, the balls are further extruded, and the spring is contracted until the balls are embedded into the grooves designed on the two opposite sides of the hoisting support rod.

5. The full-tensor magnetic field gradient measurement device oriented toward a quad-rotor drone platform of claim 1, wherein: the base line is adjustable, and the specific mode is as follows: a slideway is designed on the folding sensor mounting device, and the sensor is connected by penetrating through the slideway through a bolt; when the foldable sensor mounting device is unfolded, the position of the sensor in the left and right directions of the unmanned aerial vehicle is adjusted by the sliding of the sensor along the slide way; the foldable sensor mounting device is connected with the end part of the sole support frame through the telescopic sleeve, and when the foldable sensor mounting device is unfolded, the position of the sensor in the front-back direction of the unmanned aerial vehicle is adjusted through the telescopic action of the telescopic sleeve;

the hoisting support rod is connected with the driving device through the telescopic sleeve; when the hoist and mount bracing piece expandes, realize the position control of sensor orientation about unmanned aerial vehicle through telescopic flexible.

6. The measurement method for the full-tensor magnetic field gradient measurement device oriented to the quad-rotor drone platform of claim 1, characterized in that: the method comprises the following steps:

step 1: unfolding the foldable sensor mounting device, and adjusting the base length of the x axis, the y axis and the z axis according to the magnetic target; wherein the y-axis is along the left and right directions of the unmanned aerial vehicle; the x axis is along the front and back directions of the unmanned aerial vehicle; the z axis is along the up-down direction of the unmanned aerial vehicle;

step 2: calibrating the navigation angle of the unmanned aerial vehicle and recording; calibrating the central points of two sensors on the same side of the unmanned aerial vehicle to be positioned on the same straight line by using a straight line or a ruler;

and step 3: taking off, and then remotely controlling the steering engine to drive the hoisting support rod to be completely unfolded along the z-axis direction.

And 4, step 4: acquiring a three-axis magnetic field in real time through five sensors;

and 5: the full tensor magnetic field gradient is calculated.

7. The method of claim 6, wherein the means for measuring the full-tensor magnetic field gradient oriented quad-rotor drone platform comprises: in step 5, the full tensor magnetic field gradient calculation method comprises the following steps: the tensor magnetic field gradient of the x axis is divided by twice of the length of the x axis base after the subtraction of the sum of the three-axis magnetic characteristics of the two sensors in the same side x axis direction and the sum of the three-axis magnetic characteristics of the two sensors on the opposite side; the tensor magnetic field gradient of the y axis is divided by two times of the base length of the y axis after the subtraction of the sum of the three-axis magnetic characteristics of the two sensors in the same y axis direction and the sum of the three-axis magnetic characteristics of the two sensors on the opposite side; the z-axis tensor magnetic field gradient is divided by the two times of the z-axis base length after the subtraction of the sum of the three-axis magnetic characteristics of the two sensors on the same side with the sensor of the pendant below the unmanned aerial vehicle and the two times of the three-axis magnetic characteristics of the sensor of the pendant below the unmanned aerial vehicle.

Images